// Copyright 2023 The Tint Authors.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
//     http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.

#include "src/tint/lang/wgsl/reader/program_to_ir/program_to_ir.h"

#include <iostream>
#include <unordered_map>
#include <utility>
#include <variant>
#include <vector>

#include "src/tint/lang/core/ir/block_param.h"
#include "src/tint/lang/core/ir/builder.h"
#include "src/tint/lang/core/ir/exit_if.h"
#include "src/tint/lang/core/ir/exit_loop.h"
#include "src/tint/lang/core/ir/exit_switch.h"
#include "src/tint/lang/core/ir/function.h"
#include "src/tint/lang/core/ir/if.h"
#include "src/tint/lang/core/ir/loop.h"
#include "src/tint/lang/core/ir/module.h"
#include "src/tint/lang/core/ir/store.h"
#include "src/tint/lang/core/ir/switch.h"
#include "src/tint/lang/core/ir/value.h"
#include "src/tint/lang/core/type/pointer.h"
#include "src/tint/lang/core/type/reference.h"
#include "src/tint/lang/core/type/struct.h"
#include "src/tint/lang/core/type/void.h"
#include "src/tint/lang/wgsl/ast/accessor_expression.h"
#include "src/tint/lang/wgsl/ast/alias.h"
#include "src/tint/lang/wgsl/ast/assignment_statement.h"
#include "src/tint/lang/wgsl/ast/binary_expression.h"
#include "src/tint/lang/wgsl/ast/bitcast_expression.h"
#include "src/tint/lang/wgsl/ast/block_statement.h"
#include "src/tint/lang/wgsl/ast/bool_literal_expression.h"
#include "src/tint/lang/wgsl/ast/break_if_statement.h"
#include "src/tint/lang/wgsl/ast/break_statement.h"
#include "src/tint/lang/wgsl/ast/call_expression.h"
#include "src/tint/lang/wgsl/ast/call_statement.h"
#include "src/tint/lang/wgsl/ast/compound_assignment_statement.h"
#include "src/tint/lang/wgsl/ast/const.h"
#include "src/tint/lang/wgsl/ast/const_assert.h"
#include "src/tint/lang/wgsl/ast/continue_statement.h"
#include "src/tint/lang/wgsl/ast/diagnostic_directive.h"
#include "src/tint/lang/wgsl/ast/discard_statement.h"
#include "src/tint/lang/wgsl/ast/enable.h"
#include "src/tint/lang/wgsl/ast/float_literal_expression.h"
#include "src/tint/lang/wgsl/ast/for_loop_statement.h"
#include "src/tint/lang/wgsl/ast/function.h"
#include "src/tint/lang/wgsl/ast/id_attribute.h"
#include "src/tint/lang/wgsl/ast/identifier.h"
#include "src/tint/lang/wgsl/ast/identifier_expression.h"
#include "src/tint/lang/wgsl/ast/if_statement.h"
#include "src/tint/lang/wgsl/ast/increment_decrement_statement.h"
#include "src/tint/lang/wgsl/ast/index_accessor_expression.h"
#include "src/tint/lang/wgsl/ast/int_literal_expression.h"
#include "src/tint/lang/wgsl/ast/interpolate_attribute.h"
#include "src/tint/lang/wgsl/ast/invariant_attribute.h"
#include "src/tint/lang/wgsl/ast/let.h"
#include "src/tint/lang/wgsl/ast/literal_expression.h"
#include "src/tint/lang/wgsl/ast/loop_statement.h"
#include "src/tint/lang/wgsl/ast/member_accessor_expression.h"
#include "src/tint/lang/wgsl/ast/override.h"
#include "src/tint/lang/wgsl/ast/phony_expression.h"
#include "src/tint/lang/wgsl/ast/return_statement.h"
#include "src/tint/lang/wgsl/ast/statement.h"
#include "src/tint/lang/wgsl/ast/struct.h"
#include "src/tint/lang/wgsl/ast/struct_member_align_attribute.h"
#include "src/tint/lang/wgsl/ast/struct_member_size_attribute.h"
#include "src/tint/lang/wgsl/ast/switch_statement.h"
#include "src/tint/lang/wgsl/ast/templated_identifier.h"
#include "src/tint/lang/wgsl/ast/unary_op_expression.h"
#include "src/tint/lang/wgsl/ast/var.h"
#include "src/tint/lang/wgsl/ast/variable_decl_statement.h"
#include "src/tint/lang/wgsl/ast/while_statement.h"
#include "src/tint/lang/wgsl/program/program.h"
#include "src/tint/lang/wgsl/sem/builtin.h"
#include "src/tint/lang/wgsl/sem/call.h"
#include "src/tint/lang/wgsl/sem/function.h"
#include "src/tint/lang/wgsl/sem/index_accessor_expression.h"
#include "src/tint/lang/wgsl/sem/load.h"
#include "src/tint/lang/wgsl/sem/materialize.h"
#include "src/tint/lang/wgsl/sem/member_accessor_expression.h"
#include "src/tint/lang/wgsl/sem/module.h"
#include "src/tint/lang/wgsl/sem/switch_statement.h"
#include "src/tint/lang/wgsl/sem/value_constructor.h"
#include "src/tint/lang/wgsl/sem/value_conversion.h"
#include "src/tint/lang/wgsl/sem/value_expression.h"
#include "src/tint/lang/wgsl/sem/variable.h"
#include "src/tint/utils/containers/reverse.h"
#include "src/tint/utils/containers/scope_stack.h"
#include "src/tint/utils/macros/defer.h"
#include "src/tint/utils/macros/scoped_assignment.h"
#include "src/tint/utils/result/result.h"
#include "src/tint/utils/rtti/switch.h"

using namespace tint::number_suffixes;  // NOLINT

namespace tint::wgsl::reader {

namespace {

using ResultType = tint::Result<ir::Module, diag::List>;

/// Impl is the private-implementation of FromProgram().
class Impl {
  public:
    /// Constructor
    /// @param program the program to convert to IR
    explicit Impl(const Program* program) : program_(program) {}

    /// Builds an IR module from the program passed to the constructor.
    /// @return the IR module or an error.
    ResultType Build() { return EmitModule(); }

  private:
    enum class ControlFlags { kNone, kExcludeSwitch };

    // The input Program
    const Program* program_ = nullptr;

    /// The IR module being built
    ir::Module mod;

    /// The IR builder being used by the impl.
    ir::Builder builder_{mod};

    // The clone context used to clone data from #program_
    core::constant::CloneContext clone_ctx_{
        /* type_ctx */ core::type::CloneContext{
            /* src */ {&program_->Symbols()},
            /* dst */ {&builder_.ir.symbols, &builder_.ir.Types()},
        },
        /* dst */ {builder_.ir.constant_values},
    };

    /// The stack of flow control instructions.
    Vector<ir::ControlInstruction*, 8> control_stack_;

    struct VectorRefElementAccess {
        ir::Value* vector = nullptr;
        ir::Value* index = nullptr;
    };

    using ValueOrVecElAccess = std::variant<ir::Value*, VectorRefElementAccess>;

    /// The current block for expressions.
    ir::Block* current_block_ = nullptr;

    /// The current function being processed.
    ir::Function* current_function_ = nullptr;

    /// The current stack of scopes being processed.
    ScopeStack<Symbol, ir::Value*> scopes_;

    /// The diagnostic that have been raised.
    diag::List diagnostics_;

    class StackScope {
      public:
        explicit StackScope(Impl* impl) : impl_(impl) { impl->scopes_.Push(); }

        ~StackScope() { impl_->scopes_.Pop(); }

      protected:
        Impl* impl_;
    };

    class ControlStackScope : public StackScope {
      public:
        ControlStackScope(Impl* impl, ir::ControlInstruction* b) : StackScope(impl) {
            impl_->control_stack_.Push(b);
        }

        ~ControlStackScope() { impl_->control_stack_.Pop(); }
    };

    void add_error(const Source& s, const std::string& err) {
        diagnostics_.add_error(tint::diag::System::IR, err, s);
    }

    bool NeedTerminator() { return current_block_ && !current_block_->HasTerminator(); }

    void SetTerminator(ir::Terminator* terminator) {
        TINT_ASSERT(current_block_);
        TINT_ASSERT(!current_block_->HasTerminator());

        current_block_->Append(terminator);
        current_block_ = nullptr;
    }

    ir::Instruction* FindEnclosingControl(ControlFlags flags) {
        for (auto it = control_stack_.rbegin(); it != control_stack_.rend(); ++it) {
            if ((*it)->Is<ir::Loop>()) {
                return *it;
            }
            if (flags == ControlFlags::kExcludeSwitch) {
                continue;
            }
            if ((*it)->Is<ir::Switch>()) {
                return *it;
            }
        }
        return nullptr;
    }

    ResultType EmitModule() {
        auto* sem = program_->Sem().Module();

        for (auto* decl : sem->DependencyOrderedDeclarations()) {
            tint::Switch(
                decl,  //
                [&](const ast::Struct*) {
                    // Will be encoded into the `type::Struct` when used. We will then hoist all
                    // used structs up to module scope when converting IR.
                },
                [&](const ast::Alias*) {
                    // Folded away and doesn't appear in the IR.
                },
                [&](const ast::Variable* var) {
                    // Setup the current block to be the root block for the module. The builder
                    // will handle creating it if it doesn't exist already.
                    TINT_SCOPED_ASSIGNMENT(current_block_, builder_.RootBlock());
                    EmitVariable(var);
                },
                [&](const ast::Function* func) { EmitFunction(func); },
                [&](const ast::Enable*) {
                    // TODO(dsinclair): Implement? I think these need to be passed along so further
                    // stages know what is enabled.
                },
                [&](const ast::ConstAssert*) {
                    // Evaluated by the resolver, drop from the IR.
                },
                [&](const ast::DiagnosticDirective*) {
                    // Ignored for now.
                },
                [&](Default) {
                    add_error(decl->source, "unknown type: " + std::string(decl->TypeInfo().name));
                });
        }

        if (diagnostics_.contains_errors()) {
            return ResultType(std::move(diagnostics_));
        }

        return ResultType{std::move(mod)};
    }

    core::Interpolation ExtractInterpolation(const ast::InterpolateAttribute* interp) {
        auto type = program_->Sem()
                        .Get(interp->type)
                        ->As<sem::BuiltinEnumExpression<core::InterpolationType>>();
        core::InterpolationType interpolation_type = type->Value();

        core::InterpolationSampling interpolation_sampling =
            core::InterpolationSampling::kUndefined;
        if (interp->sampling) {
            auto sampling = program_->Sem()
                                .Get(interp->sampling)
                                ->As<sem::BuiltinEnumExpression<core::InterpolationSampling>>();
            interpolation_sampling = sampling->Value();
        }

        return core::Interpolation{interpolation_type, interpolation_sampling};
    }

    void EmitFunction(const ast::Function* ast_func) {
        // The flow stack should have been emptied when the previous function finished building.
        TINT_ASSERT(control_stack_.IsEmpty());

        const auto* sem = program_->Sem().Get(ast_func);

        auto* ir_func = builder_.Function(ast_func->name->symbol.NameView(),
                                          sem->ReturnType()->Clone(clone_ctx_.type_ctx));
        current_function_ = ir_func;

        scopes_.Set(ast_func->name->symbol, ir_func);

        if (ast_func->IsEntryPoint()) {
            switch (ast_func->PipelineStage()) {
                case ast::PipelineStage::kVertex:
                    ir_func->SetStage(ir::Function::PipelineStage::kVertex);
                    break;
                case ast::PipelineStage::kFragment:
                    ir_func->SetStage(ir::Function::PipelineStage::kFragment);
                    break;
                case ast::PipelineStage::kCompute: {
                    ir_func->SetStage(ir::Function::PipelineStage::kCompute);

                    auto wg_size = sem->WorkgroupSize();
                    ir_func->SetWorkgroupSize(wg_size[0].value(), wg_size[1].value_or(1),
                                              wg_size[2].value_or(1));
                    break;
                }
                default: {
                    TINT_ICE() << "Invalid pipeline stage";
                    return;
                }
            }

            // Note, interpolated is only valid when paired with Location, so it will only be set
            // when the location is set.
            std::optional<core::Interpolation> interpolation;
            for (auto* attr : ast_func->return_type_attributes) {
                tint::Switch(
                    attr,  //
                    [&](const ast::InterpolateAttribute* interp) {
                        interpolation = ExtractInterpolation(interp);
                    },
                    [&](const ast::InvariantAttribute*) { ir_func->SetReturnInvariant(true); },
                    [&](const ast::BuiltinAttribute* b) {
                        if (auto* ident_sem =
                                program_->Sem()
                                    .Get(b)
                                    ->As<sem::BuiltinEnumExpression<core::BuiltinValue>>()) {
                            switch (ident_sem->Value()) {
                                case core::BuiltinValue::kPosition:
                                    ir_func->SetReturnBuiltin(
                                        ir::Function::ReturnBuiltin::kPosition);
                                    break;
                                case core::BuiltinValue::kFragDepth:
                                    ir_func->SetReturnBuiltin(
                                        ir::Function::ReturnBuiltin::kFragDepth);
                                    break;
                                case core::BuiltinValue::kSampleMask:
                                    ir_func->SetReturnBuiltin(
                                        ir::Function::ReturnBuiltin::kSampleMask);
                                    break;
                                default:
                                    TINT_ICE() << "Unknown builtin value in return attributes "
                                               << ident_sem->Value();
                                    return;
                            }
                        } else {
                            TINT_ICE() << "Builtin attribute sem invalid";
                            return;
                        }
                    });
            }
            if (sem->ReturnLocation().has_value()) {
                ir_func->SetReturnLocation(sem->ReturnLocation().value(), interpolation);
            }
        }

        scopes_.Push();
        TINT_DEFER(scopes_.Pop());

        Vector<ir::FunctionParam*, 1> params;
        for (auto* p : ast_func->params) {
            const auto* param_sem = program_->Sem().Get(p)->As<sem::Parameter>();
            auto* ty = param_sem->Type()->Clone(clone_ctx_.type_ctx);
            auto* param = builder_.FunctionParam(p->name->symbol.NameView(), ty);

            // Note, interpolated is only valid when paired with Location, so it will only be set
            // when the location is set.
            std::optional<core::Interpolation> interpolation;
            for (auto* attr : p->attributes) {
                tint::Switch(
                    attr,  //
                    [&](const ast::InterpolateAttribute* interp) {
                        interpolation = ExtractInterpolation(interp);
                    },
                    [&](const ast::InvariantAttribute*) { param->SetInvariant(true); },
                    [&](const ast::BuiltinAttribute* b) {
                        if (auto* ident_sem =
                                program_->Sem()
                                    .Get(b)
                                    ->As<sem::BuiltinEnumExpression<core::BuiltinValue>>()) {
                            switch (ident_sem->Value()) {
                                case core::BuiltinValue::kVertexIndex:
                                    param->SetBuiltin(ir::FunctionParam::Builtin::kVertexIndex);
                                    break;
                                case core::BuiltinValue::kInstanceIndex:
                                    param->SetBuiltin(ir::FunctionParam::Builtin::kInstanceIndex);
                                    break;
                                case core::BuiltinValue::kPosition:
                                    param->SetBuiltin(ir::FunctionParam::Builtin::kPosition);
                                    break;
                                case core::BuiltinValue::kFrontFacing:
                                    param->SetBuiltin(ir::FunctionParam::Builtin::kFrontFacing);
                                    break;
                                case core::BuiltinValue::kLocalInvocationId:
                                    param->SetBuiltin(
                                        ir::FunctionParam::Builtin::kLocalInvocationId);
                                    break;
                                case core::BuiltinValue::kLocalInvocationIndex:
                                    param->SetBuiltin(
                                        ir::FunctionParam::Builtin::kLocalInvocationIndex);
                                    break;
                                case core::BuiltinValue::kGlobalInvocationId:
                                    param->SetBuiltin(
                                        ir::FunctionParam::Builtin::kGlobalInvocationId);
                                    break;
                                case core::BuiltinValue::kWorkgroupId:
                                    param->SetBuiltin(ir::FunctionParam::Builtin::kWorkgroupId);
                                    break;
                                case core::BuiltinValue::kNumWorkgroups:
                                    param->SetBuiltin(ir::FunctionParam::Builtin::kNumWorkgroups);
                                    break;
                                case core::BuiltinValue::kSampleIndex:
                                    param->SetBuiltin(ir::FunctionParam::Builtin::kSampleIndex);
                                    break;
                                case core::BuiltinValue::kSampleMask:
                                    param->SetBuiltin(ir::FunctionParam::Builtin::kSampleMask);
                                    break;
                                default:
                                    TINT_ICE() << "Unknown builtin value in parameter attributes "
                                               << ident_sem->Value();
                                    return;
                            }
                        } else {
                            TINT_ICE() << "Builtin attribute sem invalid";
                            return;
                        }
                    });

                if (param_sem->Location().has_value()) {
                    param->SetLocation(param_sem->Location().value(), interpolation);
                }
                if (param_sem->BindingPoint().has_value()) {
                    param->SetBindingPoint(param_sem->BindingPoint()->group,
                                           param_sem->BindingPoint()->binding);
                }
            }

            scopes_.Set(p->name->symbol, param);
            params.Push(param);
        }
        ir_func->SetParams(params);

        TINT_SCOPED_ASSIGNMENT(current_block_, ir_func->Block());
        EmitBlock(ast_func->body);

        // Add a terminator if one was not already created.
        if (NeedTerminator()) {
            if (!program_->Sem().Get(ast_func->body)->Behaviors().Contains(sem::Behavior::kNext)) {
                SetTerminator(builder_.Unreachable());
            } else {
                SetTerminator(builder_.Return(current_function_));
            }
        }

        TINT_ASSERT(control_stack_.IsEmpty());
        current_block_ = nullptr;
        current_function_ = nullptr;
    }

    void EmitStatements(VectorRef<const ast::Statement*> stmts) {
        for (auto* s : stmts) {
            EmitStatement(s);

            if (auto* sem = program_->Sem().Get(s);
                sem && !sem->Behaviors().Contains(sem::Behavior::kNext)) {
                break;  // Unreachable statement.
            }
        }
    }

    void EmitStatement(const ast::Statement* stmt) {
        tint::Switch(
            stmt,  //
            [&](const ast::AssignmentStatement* a) { EmitAssignment(a); },
            [&](const ast::BlockStatement* b) { EmitBlock(b); },
            [&](const ast::BreakStatement* b) { EmitBreak(b); },
            [&](const ast::BreakIfStatement* b) { EmitBreakIf(b); },
            [&](const ast::CallStatement* c) { EmitCall(c); },
            [&](const ast::CompoundAssignmentStatement* c) { EmitCompoundAssignment(c); },
            [&](const ast::ContinueStatement* c) { EmitContinue(c); },
            [&](const ast::DiscardStatement* d) { EmitDiscard(d); },
            [&](const ast::IfStatement* i) { EmitIf(i); },
            [&](const ast::LoopStatement* l) { EmitLoop(l); },
            [&](const ast::ForLoopStatement* l) { EmitForLoop(l); },
            [&](const ast::WhileStatement* l) { EmitWhile(l); },
            [&](const ast::ReturnStatement* r) { EmitReturn(r); },
            [&](const ast::SwitchStatement* s) { EmitSwitch(s); },
            [&](const ast::VariableDeclStatement* v) { EmitVariable(v->variable); },
            [&](const ast::IncrementDecrementStatement* i) { EmitIncrementDecrement(i); },
            [&](const ast::ConstAssert*) {
                // Not emitted
            },
            [&](Default) {
                add_error(stmt->source,
                          "unknown statement type: " + std::string(stmt->TypeInfo().name));
            });
    }

    void EmitAssignment(const ast::AssignmentStatement* stmt) {
        // If assigning to a phony, just generate the RHS and we're done. Note that, because
        // this isn't used, a subsequent transform could remove it due to it being dead code.
        // This could then change the interface for the program (i.e. a global var no longer
        // used). If that happens we have to either fix this to store to a phony value, or make
        // sure we pull the interface before doing the dead code elimination.
        if (stmt->lhs->Is<ast::PhonyExpression>()) {
            (void)EmitValueExpression(stmt->rhs);
            return;
        }

        auto lhs = EmitExpression(stmt->lhs);

        auto rhs = EmitValueExpression(stmt->rhs);
        if (!rhs) {
            return;
        }

        auto b = builder_.Append(current_block_);
        if (auto* v = std::get_if<ir::Value*>(&lhs)) {
            b.Store(*v, rhs);
        } else if (auto ref = std::get_if<VectorRefElementAccess>(&lhs)) {
            b.StoreVectorElement(ref->vector, ref->index, rhs);
        }
    }

    void EmitIncrementDecrement(const ast::IncrementDecrementStatement* stmt) {
        auto lhs = EmitExpression(stmt->lhs);

        auto* one = program_->TypeOf(stmt->lhs)->UnwrapRef()->is_signed_integer_scalar()
                        ? builder_.Constant(1_i)
                        : builder_.Constant(1_u);

        EmitCompoundAssignment(lhs, one,
                               stmt->increment ? core::BinaryOp::kAdd : core::BinaryOp::kSubtract);
    }

    void EmitCompoundAssignment(const ast::CompoundAssignmentStatement* stmt) {
        auto lhs = EmitExpression(stmt->lhs);

        auto rhs = EmitValueExpression(stmt->rhs);
        if (!rhs) {
            return;
        }

        EmitCompoundAssignment(lhs, rhs, stmt->op);
    }

    void EmitCompoundAssignment(ValueOrVecElAccess lhs, ir::Value* rhs, core::BinaryOp op) {
        auto b = builder_.Append(current_block_);
        if (auto* v = std::get_if<ir::Value*>(&lhs)) {
            auto* load = b.Load(*v);
            auto* ty = load->Result()->Type();
            auto* inst = current_block_->Append(BinaryOp(ty, load->Result(), rhs, op));
            b.Store(*v, inst);
        } else if (auto ref = std::get_if<VectorRefElementAccess>(&lhs)) {
            auto* load = b.LoadVectorElement(ref->vector, ref->index);
            auto* ty = load->Result()->Type();
            auto* inst = b.Append(BinaryOp(ty, load->Result(), rhs, op));
            b.StoreVectorElement(ref->vector, ref->index, inst);
        }
    }

    void EmitBlock(const ast::BlockStatement* block) {
        scopes_.Push();
        TINT_DEFER(scopes_.Pop());

        // Note, this doesn't need to emit a Block as the current block should be sufficient as the
        // blocks all get flattened. Each flow control node will inject the basic blocks it
        // requires.
        EmitStatements(block->statements);
    }

    void EmitIf(const ast::IfStatement* stmt) {
        // Emit the if condition into the end of the preceding block
        auto reg = EmitValueExpression(stmt->condition);
        if (!reg) {
            return;
        }
        auto* if_inst = builder_.If(reg);
        current_block_->Append(if_inst);

        {
            ControlStackScope scope(this, if_inst);

            {
                TINT_SCOPED_ASSIGNMENT(current_block_, if_inst->True());
                EmitBlock(stmt->body);

                // If the true block did not terminate, then emit an exit_if
                if (NeedTerminator()) {
                    SetTerminator(builder_.ExitIf(if_inst));
                }
            }

            if (stmt->else_statement) {
                TINT_SCOPED_ASSIGNMENT(current_block_, if_inst->False());
                EmitStatement(stmt->else_statement);

                // If the false block did not terminate, then emit an exit_if
                if (NeedTerminator()) {
                    SetTerminator(builder_.ExitIf(if_inst));
                }
            }
        }
    }

    void EmitLoop(const ast::LoopStatement* stmt) {
        auto* loop_inst = builder_.Loop();
        current_block_->Append(loop_inst);

        // Note: The loop doesn't use EmitBlock because it needs the scope stack to not get popped
        // until after the continuing block.

        ControlStackScope scope(this, loop_inst);

        {
            TINT_SCOPED_ASSIGNMENT(current_block_, loop_inst->Body());

            EmitStatements(stmt->body->statements);

            // The current block didn't `break`, `return` or `continue`, go to the continuing block.
            if (NeedTerminator()) {
                SetTerminator(builder_.Continue(loop_inst));
            }
        }

        {
            TINT_SCOPED_ASSIGNMENT(current_block_, loop_inst->Continuing());
            if (stmt->continuing) {
                EmitBlock(stmt->continuing);
            }
            // Branch back to the start block if the continue target didn't terminate already
            if (NeedTerminator()) {
                SetTerminator(builder_.NextIteration(loop_inst));
            }
        }
    }

    void EmitWhile(const ast::WhileStatement* stmt) {
        auto* loop_inst = builder_.Loop();
        current_block_->Append(loop_inst);

        ControlStackScope scope(this, loop_inst);

        // Continue is always empty, just go back to the start
        {
            TINT_SCOPED_ASSIGNMENT(current_block_, loop_inst->Continuing());
            SetTerminator(builder_.NextIteration(loop_inst));
        }

        {
            TINT_SCOPED_ASSIGNMENT(current_block_, loop_inst->Body());

            // Emit the while condition into the Start().target of the loop
            auto reg = EmitValueExpression(stmt->condition);
            if (!reg) {
                return;
            }

            // Create an `if (cond) {} else {break;}` control flow
            auto* if_inst = builder_.If(reg);
            current_block_->Append(if_inst);

            {
                TINT_SCOPED_ASSIGNMENT(current_block_, if_inst->True());
                SetTerminator(builder_.ExitIf(if_inst));
            }

            {
                TINT_SCOPED_ASSIGNMENT(current_block_, if_inst->False());
                SetTerminator(builder_.ExitLoop(loop_inst));
            }

            EmitStatements(stmt->body->statements);

            // The current block didn't `break`, `return` or `continue`, go to the continuing block.
            if (NeedTerminator()) {
                SetTerminator(builder_.Continue(loop_inst));
            }
        }
    }

    void EmitForLoop(const ast::ForLoopStatement* stmt) {
        auto* loop_inst = builder_.Loop();
        current_block_->Append(loop_inst);

        ControlStackScope scope(this, loop_inst);

        if (stmt->initializer) {
            TINT_SCOPED_ASSIGNMENT(current_block_, loop_inst->Initializer());

            // Emit the for initializer before branching to the loop body
            EmitStatement(stmt->initializer);

            if (NeedTerminator()) {
                SetTerminator(builder_.NextIteration(loop_inst));
            }
        }

        TINT_SCOPED_ASSIGNMENT(current_block_, loop_inst->Body());

        if (stmt->condition) {
            // Emit the condition into the target target of the loop body
            auto reg = EmitValueExpression(stmt->condition);
            if (!reg) {
                return;
            }

            // Create an `if (cond) {} else {break;}` control flow
            auto* if_inst = builder_.If(reg);
            current_block_->Append(if_inst);

            {
                TINT_SCOPED_ASSIGNMENT(current_block_, if_inst->True());
                SetTerminator(builder_.ExitIf(if_inst));
            }

            {
                TINT_SCOPED_ASSIGNMENT(current_block_, if_inst->False());
                SetTerminator(builder_.ExitLoop(loop_inst));
            }
        }

        EmitBlock(stmt->body);
        if (NeedTerminator()) {
            SetTerminator(builder_.Continue(loop_inst));
        }

        if (stmt->continuing) {
            TINT_SCOPED_ASSIGNMENT(current_block_, loop_inst->Continuing());
            EmitStatement(stmt->continuing);
            SetTerminator(builder_.NextIteration(loop_inst));
        }
    }

    void EmitSwitch(const ast::SwitchStatement* stmt) {
        // Emit the condition into the preceding block
        auto reg = EmitValueExpression(stmt->condition);
        if (!reg) {
            return;
        }
        auto* switch_inst = builder_.Switch(reg);
        current_block_->Append(switch_inst);

        ControlStackScope scope(this, switch_inst);

        const auto* sem = program_->Sem().Get(stmt);
        for (const auto* c : sem->Cases()) {
            Vector<ir::Switch::CaseSelector, 4> selectors;
            for (const auto* selector : c->Selectors()) {
                if (selector->IsDefault()) {
                    selectors.Push({nullptr});
                } else {
                    selectors.Push({builder_.Constant(selector->Value()->Clone(clone_ctx_))});
                }
            }

            TINT_SCOPED_ASSIGNMENT(current_block_, builder_.Case(switch_inst, selectors));
            EmitBlock(c->Body()->Declaration());

            if (NeedTerminator()) {
                SetTerminator(builder_.ExitSwitch(switch_inst));
            }
        }
    }

    void EmitReturn(const ast::ReturnStatement* stmt) {
        ir::Value* ret_value = nullptr;
        if (stmt->value) {
            auto ret = EmitValueExpression(stmt->value);
            if (!ret) {
                return;
            }
            ret_value = ret;
        }
        if (ret_value) {
            SetTerminator(builder_.Return(current_function_, ret_value));
        } else {
            SetTerminator(builder_.Return(current_function_));
        }
    }

    void EmitBreak(const ast::BreakStatement*) {
        auto* current_control = FindEnclosingControl(ControlFlags::kNone);
        TINT_ASSERT(current_control);

        if (auto* c = current_control->As<ir::Loop>()) {
            SetTerminator(builder_.ExitLoop(c));
        } else if (auto* s = current_control->As<ir::Switch>()) {
            SetTerminator(builder_.ExitSwitch(s));
        } else {
            TINT_UNREACHABLE();
        }
    }

    void EmitContinue(const ast::ContinueStatement*) {
        auto* current_control = FindEnclosingControl(ControlFlags::kExcludeSwitch);
        TINT_ASSERT(current_control);

        if (auto* c = current_control->As<ir::Loop>()) {
            SetTerminator(builder_.Continue(c));
        } else {
            TINT_UNREACHABLE();
        }
    }

    // Discard is being treated as an instruction. The semantics in WGSL is demote_to_helper, so
    // the code has to continue as before it just predicates writes. If WGSL grows some kind of
    // terminating discard that would probably make sense as a Block but would then require
    // figuring out the multi-level exit that is triggered.
    void EmitDiscard(const ast::DiscardStatement*) {
        auto* inst = builder_.Discard();
        current_block_->Append(inst);
    }

    void EmitBreakIf(const ast::BreakIfStatement* stmt) {
        auto* current_control = FindEnclosingControl(ControlFlags::kExcludeSwitch);

        // Emit the break-if condition into the end of the preceding block
        auto cond = EmitValueExpression(stmt->condition);
        if (!cond) {
            return;
        }
        SetTerminator(builder_.BreakIf(current_control->As<ir::Loop>(), cond));
    }

    ValueOrVecElAccess EmitExpression(const ast::Expression* root) {
        struct Emitter {
            explicit Emitter(Impl& i) : impl(i) {}

            ValueOrVecElAccess Emit(const ast::Expression* root) {
                // Process the root expression. This will likely add tasks.
                Process(root);

                // Execute all the tasks until all expressions have been resolved.
                while (!tasks.IsEmpty()) {
                    auto task = tasks.Pop();
                    task();
                }

                // Get the resolved root expression.
                return Get(root);
            }

          private:
            Impl& impl;
            Vector<ir::Block*, 8> blocks;
            Vector<std::function<void()>, 64> tasks;
            Hashmap<const ast::Expression*, ValueOrVecElAccess, 64> bindings_;

            void Bind(const ast::Expression* expr, ir::Value* value) {
                // If this expression maps to sem::Load, insert a load instruction to get the result
                if (impl.program_->Sem().Get<sem::Load>(expr)) {
                    auto* load = impl.builder_.Load(value);
                    impl.current_block_->Append(load);
                    value = load->Result();
                }
                bindings_.Add(expr, value);
            }

            void Bind(const ast::Expression* expr, const VectorRefElementAccess& access) {
                // If this expression maps to sem::Load, insert a load instruction to get the result
                if (impl.program_->Sem().Get<sem::Load>(expr)) {
                    auto* load = impl.builder_.LoadVectorElement(access.vector, access.index);
                    impl.current_block_->Append(load);
                    bindings_.Add(expr, load->Result());
                } else {
                    bindings_.Add(expr, access);
                }
            }

            ValueOrVecElAccess Get(const ast::Expression* expr) {
                auto val = bindings_.Get(expr);
                if (!val) {
                    return nullptr;
                }
                return *val;
            }

            ir::Value* GetValue(const ast::Expression* expr) {
                auto res = Get(expr);
                if (auto** val = std::get_if<ir::Value*>(&res)) {
                    return *val;
                }
                TINT_ICE() << "expression did not resolve to a value";
                return nullptr;
            }

            void PushBlock(ir::Block* block) {
                blocks.Push(impl.current_block_);
                impl.current_block_ = block;
            }

            void PopBlock() { impl.current_block_ = blocks.Pop(); }

            ir::Value* EmitConstant(const ast::Expression* expr) {
                if (auto* sem = impl.program_->Sem().GetVal(expr)) {
                    if (auto* v = sem->ConstantValue()) {
                        if (auto* cv = v->Clone(impl.clone_ctx_)) {
                            auto* val = impl.builder_.Constant(cv);
                            bindings_.Add(expr, val);
                            return val;
                        }
                    }
                }
                return nullptr;
            }

            void EmitAccess(const ast::AccessorExpression* expr) {
                if (auto vec_access = AsVectorRefElementAccess(expr)) {
                    Bind(expr, vec_access.value());
                    return;
                }

                auto* obj = GetValue(expr->object);
                if (!obj) {
                    TINT_UNREACHABLE() << "no object result";
                    return;
                }

                auto* sem = impl.program_->Sem().Get(expr)->Unwrap();

                // The access result type should match the source result type. If the source is a
                // pointer, we generate a pointer.
                const core::type::Type* ty =
                    sem->Type()->UnwrapRef()->Clone(impl.clone_ctx_.type_ctx);
                if (auto* ptr = obj->Type()->As<core::type::Pointer>();
                    ptr && !ty->Is<core::type::Pointer>()) {
                    ty = impl.builder_.ir.Types().ptr(ptr->AddressSpace(), ty, ptr->Access());
                }

                auto index = tint::Switch(
                    sem,
                    [&](const sem::IndexAccessorExpression* idx) -> ir::Value* {
                        if (auto* v = idx->Index()->ConstantValue()) {
                            if (auto* cv = v->Clone(impl.clone_ctx_)) {
                                return impl.builder_.Constant(cv);
                            }
                            TINT_UNREACHABLE() << "constant clone failed";
                            return nullptr;
                        }
                        return GetValue(idx->Index()->Declaration());
                    },
                    [&](const sem::StructMemberAccess* access) -> ir::Value* {
                        return impl.builder_.Constant(u32((access->Member()->Index())));
                    },
                    [&](const sem::Swizzle* swizzle) -> ir::Value* {
                        auto& indices = swizzle->Indices();

                        // A single element swizzle is just treated as an accessor.
                        if (indices.Length() == 1) {
                            return impl.builder_.Constant(u32(indices[0]));
                        }
                        auto* val = impl.builder_.Swizzle(ty, obj, std::move(indices));
                        impl.current_block_->Append(val);
                        Bind(expr, val->Result());
                        return nullptr;
                    },
                    [&](Default) {
                        TINT_ICE() << "invalid accessor: " + std::string(sem->TypeInfo().name);
                        return nullptr;
                    });

                if (!index) {
                    return;
                }

                // If the object is an unnamed value (a subexpression, not a let) and is the result
                // of another access, then we can just append the index to that access.
                if (!impl.mod.NameOf(obj).IsValid()) {
                    if (auto* inst_res = obj->As<ir::InstructionResult>()) {
                        if (auto* access = inst_res->Source()->As<ir::Access>()) {
                            access->AddIndex(index);
                            access->Result()->SetType(ty);
                            bindings_.Remove(expr->object);
                            // Move the access after the index expression.
                            if (impl.current_block_->Back() != access) {
                                impl.current_block_->Remove(access);
                                impl.current_block_->Append(access);
                            }
                            Bind(expr, access->Result());
                            return;
                        }
                    }
                }

                // Create a new access
                auto* access = impl.builder_.Access(ty, obj, index);
                impl.current_block_->Append(access);
                Bind(expr, access->Result());
            }

            void EmitBinary(const ast::BinaryExpression* b) {
                auto* b_sem = impl.program_->Sem().Get(b);
                auto* ty = b_sem->Type()->Clone(impl.clone_ctx_.type_ctx);
                auto lhs = GetValue(b->lhs);
                if (!lhs) {
                    return;
                }
                auto rhs = GetValue(b->rhs);
                if (!rhs) {
                    return;
                }
                ir::Binary* inst = impl.BinaryOp(ty, lhs, rhs, b->op);
                if (!inst) {
                    return;
                }
                impl.current_block_->Append(inst);
                Bind(b, inst->Result());
            }

            void EmitUnary(const ast::UnaryOpExpression* expr) {
                auto val = GetValue(expr->expr);
                if (!val) {
                    return;
                }
                auto* sem = impl.program_->Sem().Get(expr);
                auto* ty = sem->Type()->Clone(impl.clone_ctx_.type_ctx);
                ir::Instruction* inst = nullptr;
                switch (expr->op) {
                    case core::UnaryOp::kAddressOf:
                    case core::UnaryOp::kIndirection:
                        // 'address-of' and 'indirection' just fold away and we propagate the
                        // pointer.
                        Bind(expr, val);
                        return;
                    case core::UnaryOp::kComplement:
                        inst = impl.builder_.Complement(ty, val);
                        break;
                    case core::UnaryOp::kNegation:
                        inst = impl.builder_.Negation(ty, val);
                        break;
                    case core::UnaryOp::kNot:
                        inst = impl.builder_.Not(ty, val);
                        break;
                }
                impl.current_block_->Append(inst);
                Bind(expr, inst->Result());
            }

            void EmitBitcast(const ast::BitcastExpression* b) {
                auto val = GetValue(b->expr);
                if (!val) {
                    return;
                }
                auto* sem = impl.program_->Sem().Get(b);
                auto* ty = sem->Type()->Clone(impl.clone_ctx_.type_ctx);
                auto* inst = impl.builder_.Bitcast(ty, val);
                impl.current_block_->Append(inst);
                Bind(b, inst->Result());
            }

            void EmitCall(const ast::CallExpression* expr) {
                // If this is a materialized semantic node, just use the constant value.
                if (auto* mat = impl.program_->Sem().Get(expr)) {
                    if (mat->ConstantValue()) {
                        auto* cv = mat->ConstantValue()->Clone(impl.clone_ctx_);
                        if (!cv) {
                            impl.add_error(expr->source, "failed to get constant value for call " +
                                                             std::string(expr->TypeInfo().name));
                            return;
                        }
                        Bind(expr, impl.builder_.Constant(cv));
                        return;
                    }
                }
                Vector<ir::Value*, 8> args;
                args.Reserve(expr->args.Length());
                // Emit the arguments
                for (const auto* arg : expr->args) {
                    auto value = GetValue(arg);
                    if (!value) {
                        impl.add_error(arg->source, "failed to convert arguments");
                        return;
                    }
                    args.Push(value);
                }
                auto* sem = impl.program_->Sem().Get<sem::Call>(expr);
                if (!sem) {
                    impl.add_error(expr->source, "failed to get semantic information for call " +
                                                     std::string(expr->TypeInfo().name));
                    return;
                }
                auto* ty = sem->Target()->ReturnType()->Clone(impl.clone_ctx_.type_ctx);
                ir::Instruction* inst = nullptr;
                // If this is a builtin function, emit the specific builtin value
                if (auto* b = sem->Target()->As<sem::Builtin>()) {
                    inst = impl.builder_.Call(ty, b->Type(), args);
                } else if (sem->Target()->As<sem::ValueConstructor>()) {
                    inst = impl.builder_.Construct(ty, std::move(args));
                } else if (sem->Target()->Is<sem::ValueConversion>()) {
                    inst = impl.builder_.Convert(ty, args[0]);
                } else if (expr->target->identifier->Is<ast::TemplatedIdentifier>()) {
                    TINT_UNIMPLEMENTED() << "missing templated ident support";
                    return;
                } else {
                    // Not a builtin and not a templated call, so this is a user function.
                    inst = impl.builder_.Call(
                        ty, impl.scopes_.Get(expr->target->identifier->symbol)->As<ir::Function>(),
                        std::move(args));
                }
                if (inst == nullptr) {
                    return;
                }
                impl.current_block_->Append(inst);
                Bind(expr, inst->Result());
            }

            void EmitIdentifier(const ast::IdentifierExpression* i) {
                auto* v = impl.scopes_.Get(i->identifier->symbol);
                if (TINT_UNLIKELY(!v)) {
                    impl.add_error(i->source,
                                   "unable to find identifier " + i->identifier->symbol.Name());
                    return;
                }
                Bind(i, v);
            }

            void EmitLiteral(const ast::LiteralExpression* lit) {
                auto* sem = impl.program_->Sem().Get(lit);
                if (!sem) {
                    impl.add_error(lit->source, "failed to get semantic information for node " +
                                                    std::string(lit->TypeInfo().name));
                    return;
                }
                auto* cv = sem->ConstantValue()->Clone(impl.clone_ctx_);
                if (!cv) {
                    impl.add_error(lit->source, "failed to get constant value for node " +
                                                    std::string(lit->TypeInfo().name));
                    return;
                }
                auto* val = impl.builder_.Constant(cv);
                Bind(lit, val);
            }

            std::optional<VectorRefElementAccess> AsVectorRefElementAccess(
                const ast::Expression* expr) {
                return AsVectorRefElementAccess(
                    impl.program_->Sem().Get<sem::ValueExpression>(expr)->UnwrapLoad());
            }

            std::optional<VectorRefElementAccess> AsVectorRefElementAccess(
                const sem::ValueExpression* expr) {
                auto* access = As<sem::AccessorExpression>(expr);
                if (!access) {
                    return std::nullopt;
                }

                auto* ref = access->Object()->Type()->As<core::type::Reference>();
                if (!ref) {
                    return std::nullopt;
                }

                if (!ref->StoreType()->Is<core::type::Vector>()) {
                    return std::nullopt;
                }
                return tint::Switch(
                    access,
                    [&](const sem::Swizzle* s) -> std::optional<VectorRefElementAccess> {
                        if (auto vec = GetValue(access->Object()->Declaration())) {
                            return VectorRefElementAccess{
                                vec, impl.builder_.Constant(u32(s->Indices()[0]))};
                        }
                        return std::nullopt;
                    },
                    [&](const sem::IndexAccessorExpression* i)
                        -> std::optional<VectorRefElementAccess> {
                        if (auto vec = GetValue(access->Object()->Declaration())) {
                            if (auto idx = GetValue(i->Index()->Declaration())) {
                                return VectorRefElementAccess{vec, idx};
                            }
                        }
                        return std::nullopt;
                    });
            }

            void BeginShortCircuit(const ast::BinaryExpression* expr) {
                auto lhs = GetValue(expr->lhs);
                if (!lhs) {
                    return;
                }

                auto& b = impl.builder_;
                auto* if_inst = b.If(lhs);
                impl.current_block_->Append(if_inst);

                auto* result = b.InstructionResult(b.ir.Types().bool_());
                if_inst->SetResults(result);

                if (expr->op == core::BinaryOp::kLogicalAnd) {
                    if_inst->False()->Append(b.ExitIf(if_inst, b.Constant(false)));
                    PushBlock(if_inst->True());
                } else {
                    if_inst->True()->Append(b.ExitIf(if_inst, b.Constant(true)));
                    PushBlock(if_inst->False());
                }

                Bind(expr, result);
            }

            void EndShortCircuit(const ast::BinaryExpression* b) {
                auto res = GetValue(b);
                auto* src = res->As<ir::InstructionResult>()->Source();
                auto* if_ = src->As<ir::If>();
                TINT_ASSERT_OR_RETURN(if_);
                auto rhs = GetValue(b->rhs);
                if (!rhs) {
                    return;
                }
                impl.current_block_->Append(impl.builder_.ExitIf(if_, rhs));
                PopBlock();
            }

            void Process(const ast::Expression* expr) {
                if (EmitConstant(expr)) {
                    // If this is a value that has been const-eval'd, then no need to traverse
                    // deeper.
                    return;
                }

                tint::Switch(
                    expr,  //
                    [&](const ast::BinaryExpression* e) {
                        if (e->op == core::BinaryOp::kLogicalAnd ||
                            e->op == core::BinaryOp::kLogicalOr) {
                            tasks.Push([=] { EndShortCircuit(e); });
                            tasks.Push([=] { Process(e->rhs); });
                            tasks.Push([=] { BeginShortCircuit(e); });
                            tasks.Push([=] { Process(e->lhs); });
                        } else {
                            tasks.Push([=] { EmitBinary(e); });
                            tasks.Push([=] { Process(e->rhs); });
                            tasks.Push([=] { Process(e->lhs); });
                        }
                    },
                    [&](const ast::IndexAccessorExpression* e) {
                        tasks.Push([=] { EmitAccess(e); });
                        tasks.Push([=] { Process(e->index); });
                        tasks.Push([=] { Process(e->object); });
                    },
                    [&](const ast::MemberAccessorExpression* e) {
                        tasks.Push([=] { EmitAccess(e); });
                        tasks.Push([=] { Process(e->object); });
                    },
                    [&](const ast::UnaryOpExpression* e) {
                        tasks.Push([=] { EmitUnary(e); });
                        tasks.Push([=] { Process(e->expr); });
                    },
                    [&](const ast::CallExpression* e) {
                        tasks.Push([=] { EmitCall(e); });
                        for (auto* arg : tint::Reverse(e->args)) {
                            tasks.Push([=] { Process(arg); });
                        }
                    },
                    [&](const ast::BitcastExpression* e) {
                        tasks.Push([=] { EmitBitcast(e); });
                        tasks.Push([=] { Process(e->expr); });
                    },
                    [&](const ast::LiteralExpression* e) { EmitLiteral(e); },
                    [&](const ast::IdentifierExpression* e) { EmitIdentifier(e); },
                    [&](Default) {
                        impl.add_error(expr->source,
                                       "Unhandled: " + std::string(expr->TypeInfo().name));
                    });
            }
        };

        return Emitter(*this).Emit(root);
    }

    ir::Value* EmitValueExpression(const ast::Expression* root) {
        auto res = EmitExpression(root);
        if (auto** val = std::get_if<ir::Value*>(&res)) {
            return *val;
        }
        TINT_ICE() << "expression did not resolve to a value";
        return nullptr;
    }

    void EmitCall(const ast::CallStatement* stmt) { (void)EmitValueExpression(stmt->expr); }

    void EmitVariable(const ast::Variable* var) {
        auto* sem = program_->Sem().Get(var);

        return tint::Switch(  //
            var,
            [&](const ast::Var* v) {
                auto* ref = sem->Type()->As<core::type::Reference>();
                auto* ty = builder_.ir.Types().Get<core::type::Pointer>(
                    ref->AddressSpace(), ref->StoreType()->Clone(clone_ctx_.type_ctx),
                    ref->Access());

                auto* val = builder_.Var(ty);
                if (v->initializer) {
                    auto init = EmitValueExpression(v->initializer);
                    if (!init) {
                        return;
                    }
                    val->SetInitializer(init);
                }
                current_block_->Append(val);

                if (auto* gv = sem->As<sem::GlobalVariable>(); gv && var->HasBindingPoint()) {
                    val->SetBindingPoint(gv->BindingPoint().value().group,
                                         gv->BindingPoint().value().binding);
                }

                // Store the declaration so we can get the instruction to store too
                scopes_.Set(v->name->symbol, val->Result());

                // Record the original name of the var
                builder_.ir.SetName(val, v->name->symbol.Name());
            },
            [&](const ast::Let* l) {
                auto* last_stmt = current_block_->Back();
                auto init = EmitValueExpression(l->initializer);
                if (!init) {
                    return;
                }

                auto* value = init;
                if (current_block_->Back() == last_stmt) {
                    // Emitting the let's initializer didn't create an instruction.
                    // Create an ir::Let to give the let an instruction. This gives the let a
                    // place of declaration and name, which preserves runtime semantics of the
                    // let, and can be used by consumers of the IR to produce a variable or
                    // debug info.
                    auto* let = current_block_->Append(builder_.Let(l->name->symbol.Name(), value));
                    value = let->Result();
                } else {
                    // Record the original name of the let
                    builder_.ir.SetName(value, l->name->symbol.Name());
                }

                // Store the results of the initialization
                scopes_.Set(l->name->symbol, value);
            },
            [&](const ast::Override*) {
                add_error(var->source,
                          "found an `Override` variable. The SubstituteOverrides "
                          "transform must be run before converting to IR");
            },
            [&](const ast::Const*) {
                // Skip. This should be handled by const-eval already, so the const will be a
                // `core::constant::` value at the usage sites. Can just ignore the `const` variable
                // as it should never be used.
                //
                // TODO(dsinclair): Probably want to store the const variable somewhere and then
                // in identifier expression log an error if we ever see a const identifier. Add
                // this when identifiers and variables are supported.
            },
            [&](Default) {
                add_error(var->source, "unknown variable: " + std::string(var->TypeInfo().name));
            });
    }

    ir::Binary* BinaryOp(const core::type::Type* ty,
                         ir::Value* lhs,
                         ir::Value* rhs,
                         core::BinaryOp op) {
        switch (op) {
            case core::BinaryOp::kAnd:
                return builder_.And(ty, lhs, rhs);
            case core::BinaryOp::kOr:
                return builder_.Or(ty, lhs, rhs);
            case core::BinaryOp::kXor:
                return builder_.Xor(ty, lhs, rhs);
            case core::BinaryOp::kEqual:
                return builder_.Equal(ty, lhs, rhs);
            case core::BinaryOp::kNotEqual:
                return builder_.NotEqual(ty, lhs, rhs);
            case core::BinaryOp::kLessThan:
                return builder_.LessThan(ty, lhs, rhs);
            case core::BinaryOp::kGreaterThan:
                return builder_.GreaterThan(ty, lhs, rhs);
            case core::BinaryOp::kLessThanEqual:
                return builder_.LessThanEqual(ty, lhs, rhs);
            case core::BinaryOp::kGreaterThanEqual:
                return builder_.GreaterThanEqual(ty, lhs, rhs);
            case core::BinaryOp::kShiftLeft:
                return builder_.ShiftLeft(ty, lhs, rhs);
            case core::BinaryOp::kShiftRight:
                return builder_.ShiftRight(ty, lhs, rhs);
            case core::BinaryOp::kAdd:
                return builder_.Add(ty, lhs, rhs);
            case core::BinaryOp::kSubtract:
                return builder_.Subtract(ty, lhs, rhs);
            case core::BinaryOp::kMultiply:
                return builder_.Multiply(ty, lhs, rhs);
            case core::BinaryOp::kDivide:
                return builder_.Divide(ty, lhs, rhs);
            case core::BinaryOp::kModulo:
                return builder_.Modulo(ty, lhs, rhs);
            case core::BinaryOp::kLogicalAnd:
            case core::BinaryOp::kLogicalOr:
                TINT_ICE() << "short circuit op should have already been handled";
                return nullptr;
        }
        TINT_UNREACHABLE();
        return nullptr;
    }
};

}  // namespace

tint::Result<ir::Module, std::string> ProgramToIR(const Program* program) {
    if (!program->IsValid()) {
        return std::string("input program is not valid");
    }

    Impl b(program);
    auto r = b.Build();
    if (!r) {
        return r.Failure().str();
    }

    return r.Move();
}

}  // namespace tint::wgsl::reader
